KR20160060123A - On-line plating adhesion determination device for galvannealed steel sheet and galvannealed steel sheet production line - Google Patents

Abstract

The on-line plating adhesion determination device of the galvannealed galvanized steel sheet includes: an X-ray conduit for irradiating an X-ray toward an alloyed hot-dip galvanized steel sheet running on a transfer line; An optical system for irradiating and diffracting the X-ray generated from the X-ray tube to the galvannealed galvanized steel sheet as a parallel beam; And a detector provided at a position for detecting a diffracted X-ray having a crystal lattice plane spacing d of 1.5 ANGSTROM or more, wherein the X-ray emitted beam luminance is 20 W / mm < 2 > or more , And the gain in the width direction of the X-ray in the optical system is 0.15 or more. The crystal lattice plane spacing d may be 1.914 Å. Further, the energy of the incident X-rays from the X-ray tube may be smaller than the fluorescence X-ray excitation energy of Fe-K ?.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot-dip galvanized steel sheet for use in a hot-dip galvanized steel sheet,

The present invention relates to an on-line plating adhesion determination apparatus and an alloyed hot-dip galvanized steel sheet production line of a galvannealed galvanized steel sheet.

The galvannealed galvanized steel sheet is widely used in the world as an automotive steel sheet. The quality characteristics required of the galvannealed galvanized steel sheet include corrosion resistance, paintability, weldability, resistance to intumescence during press molding, and flaking resistance. The Fe-Zn phase constituting the plating layer of the galvannealed galvanized steel sheet includes ζ phase, δ ₁ phase and Γ · Γ ₁ phase. Among these properties, the press formability typified by the inner powdering property and the anti-flaking property is mainly dependent on the amount of formation of ζ phase and Γ · Γ ₁ phase. The powdering resistance becomes better as the Γ · Γ ₁ phase becomes smaller, and the flaking resistance becomes better as the ζ phase becomes smaller. Therefore, in order to obtain good press formability, a plating layer of a delta ₁ phase phase body is required.

It is necessary to optimize the plating bath composition (Al concentration in the bath), the bath temperature of the plating bath, and the heating and cooling conditions of the steel material in accordance with the steel material components in order to make the plated layer the δ ₁ phase main body. The Al concentration or the bath temperature in the bath is usually kept within a certain range. Then, the heating and cooling patterns considered to be optimum are determined and operated according to the alloying speed of the steel material. Actually, however, depending on the operating conditions in the upper process (the process preceding the plating) such as hot rolling, for example, alloying is performed for each coil, for each coil, and even for the same coil, The speed may change. As a result, every time the operator checks the degree of alloying with eyes, the heating and cooling conditions are finely adjusted. As a result, whether or not an alloy phase was obtained, and whether the anti-powdering property and flaking resistance were good was confirmed by testing and analyzing the representative portion of the coil (usually, the front portion and / or the tail portion) have.

However, such a method of confirming the plating quality by offline testing and analysis is not capable of prompt feedback to the operating conditions. As a result, for example, when the alloying speed is changed due to the change of the steel grade, there is a risk of deteriorating the yield. Further, depending on the winding conditions of the hot rolled coil, for example, there may be a case where the front portion of the coil is alloyed slowly compared with the middle portion. In this case, when the alloying condition is adjusted to the front portion, the middle portion becomes an alloy with the coil, It is assumed that the powdering ring is present in most cases.

In order to prevent these problems in advance, on-line measurement with high accuracy over the entire coil length is effective. The technique which is carried out for this purpose is the online X-ray diffraction method. The X-ray diffraction method is a method of performing qualitative and quantitative evaluation of a crystal phase in a plating layer by using a diffraction phenomenon that occurs when X-rays are irradiated on a crystal. When this is used for on-line measurement, it is necessary to select a diffraction X-ray having a good correlation between the diffraction X-ray intensity and the crystal phase thickness, for example. Further, in order to obtain high measurement accuracy, it is necessary to select a diffracted X-ray having a large intensity from a practical diffraction angle range.

Patent Literatures 1 and 2 disclose that practical angle of diffraction (2θ) ranges from 2θ> 80 ° (crystal lattice plane interval: d <1.78 Å when Cr reference is used as X-ray reference) And the influence of the incident X-ray intensity fluctuation is small. As the crystal lattice spacing satisfying the above conditions, for example, as described in Patent Documents 2 to 5, the ζ phase is d = 1.26 Å (2 慮 = 130 째 in Cr reference) and 隆₁ phase is d = 1.28 Å (2θ = 127 ° in the Cr reference) and Γ · Γ ₁ phase is d = 1.22 Å (2θ = 139 ° in the Cr reference).

However, in the on-line X-ray diffraction method of the prior art, it is never sufficient to carry out on-line measurement with high precision over the entire length of the coil and to quickly feed back the results to the operating conditions to prevent over- Can not. The maximum reason is that the three diffraction X-ray peaks represented by each phase of ζ phase, δ ₁ phase and Γ · Γ ₁ conventionally used are present in a region adjacent to each other and also in a region having a high and uneven background Because. The prior art, the thermal influence and the incident X-effect line intensity variations from the shaking motion, the steel plate of the steel plate a small range of 2θ> constraint that 80 ° and a third phase (ζ-phase, δ ₁ phase, Γ · Γ ₁ the ) Of the diffracted X-rays are adjacent to each other. As a result, it is extremely insufficient to achieve the original purpose of measuring the thickness of each image with high accuracy.

In addition, in recent years, in order to improve the productivity of the production line and to enhance the competitiveness, the production line of the galvannealed galvanized steel sheet has been accelerated. In order to determine the plating adhesion of the galvannealed galvanized steel sheet on-line in an accelerated manufacturing line, it is necessary to shorten the analysis time required for determination of the adhesion of the plating. In order to determine significantly the difference between the steel plate having good plating adhesion and the steel plate having poor plating adhesion, it is necessary that there is a significant difference between the measured values of both of them at least three times (3?) Of the measurement deviation.

The longer the analysis time required for the determination, the longer the length of the steel strip passing between the start of the determination and the completion of the determination, and the longer the length of the steel strip required for the determination becomes. If this becomes excessively long, quality assurance over the entire length of the coil becomes difficult, and rapid feedback to the operating conditions becomes difficult. In order to enable measurement in a shorter time, it is necessary to improve the signal strength and S / N ratio. Further, since the vibration of the steel plate increases with the increase in the speed, it is necessary to further reduce the influence of the steel plate vibration on the signal.

Patent Document 6 discloses a technique for reducing the influence of steel plate vibration. In Patent Document 6, the incident X-ray beam is incident on the multilayer mirror to be parallelized. As a result, the diffracted X-rays generated by the irradiation of the incident X-ray beam on the surface of the steel sheet are parallelized. Therefore, even when the diffraction position of the X-ray and the distance of the detection system vary due to the vibration of the steel sheet, Strength is stable.

The effect of the multilayer mirror is also described in Non-Patent Document 1. An example using a multilayer mirror and a parallel slit is disclosed in order to efficiently collimate a diverging beam from an X-ray source in a laboratory.

Japanese Patent Application Laid-Open No. 52-21887 Japanese Patent Application Laid-Open No. 5-45305 Japanese Patent Application Laid-Open No. 9-33455 Japanese Patent Application Laid-Open No. 7-260715 Japanese Patent Application Laid-Open No. 4-110644 Japanese Patent Application Laid-Open No. 2002-168811

"Advances in X-ray analysis 31", P11-27, 2000, published by Agnes Technology Center

An object of the present invention is to provide an online plating adhesion determination device and an alloyed hot-dip galvanized steel sheet production line of a galvannealed hot-dip galvanized steel sheet capable of following up the speed of a production line in the future, in view of the above circumstances.

The inventors of the present invention have focused on the fact that the background intensity is low and flat (close to horizontal) in the range where the diffraction angle 2? Is in the low angle side. As a result, it was found that a plurality of diffracted X-ray peaks of each phase existed on the lower angle side corresponding to the crystal lattice plane spacing d of 1.5 ANGSTROM or more. As a result of repeated studies on the quantitative properties of these peaks, it has been found that peaks corresponding to the respective phases, which have excellent quantitative properties and low background strength, are identified. Of these, by using the value obtained by subtracting the background intensity from the intensity of the diffraction X-ray corresponding to the crystal lattice plane spacing d of 1.914A, the thickness of Γ · Γ ₁ , which affects the plating adhesion of the galvannealed steel sheet, I found that I could measure the road.

Then, the present inventors proceeded to investigate the actualization. In order to apply the invention to a production line having a high passing speed of the steel sheet, it is necessary to solve the problem of vibration of the steel sheet at the time of passing. On the basis of the idea that a parallel beam optical system should be used as an optical system in order to alleviate the influence of the steel plate vibration, a Fe-Zn phase low angle peak corresponding to a crystal lattice plane spacing d of 1.5 angstroms or more in the parallel beam optical system is detected How to do it, and how to do it. As a result, it has been found out that, in the specification of the X-ray tube, the selection of the output, the focal size, the take-out angle and the extraction method are important for improving the sensitivity. Next, the specifications of the optical system for efficiently irradiating the sample with the beam emerging from the X-ray tube, and again guiding it to the detector, were examined. As a result, it has been found that the detection efficiency can be improved by appropriately setting the capture angle and the reflectance, particularly in the incident optical system. Therefore, the inventors of the present invention have conducted systematic experiments by changing these parameters. As a result, when the parallel beam optical system is taken as a premise, the two parameters, &quot; emitted beam luminance &quot; It has been found that the objective diffraction peak can be detected with sensitivity by designing the X-ray tube and optical system. Therefore, the present inventors have made an online X-ray diffraction apparatus that satisfies the above-mentioned conditions, and it has been found that the on-line X-ray diffraction apparatus is fabricated, and after the alloying of the continuous hot-dip galvanizing line and after the coil winding, Mm, it has been found that the on-line adhesion determination of the galvannealed zinc plating can actually be performed in a short time with high accuracy, and the present invention has been accomplished.

The present invention has been made based on the above-described findings, and its gist of the invention is as follows.

(1) That is, an on-line plating adhesion determination device of a galvannealed galvanized steel sheet according to one aspect of the present invention includes: an X-ray guide for irradiating X-ray toward an alloyed hot-dip galvanized steel sheet running on a transfer line; An optical system for irradiating and diffracting the X-ray generated from the X-ray tube to the galvannealed steel sheet as a parallel beam; And a detector provided at a position for detecting a diffracted X-ray having a crystal lattice plane spacing d of 1.5 ANGSTROM or more, wherein the X-ray emitted beam luminance is 20 W / mm &lt; 2 &gt; , And the gain in the width direction of the X-ray in the optical system is 0.15 or more.

(2) The on-line plating adhesion determination device for a galvannealed galvanized steel sheet according to (1), wherein the detector is provided at a position of a diffraction angle for detecting the diffracted X-ray having a crystal lattice plane spacing d of 1.914 .

(3) The on-line plating adhesion determination device for a galvannealed galvanized steel sheet according to (1) or (2), wherein the X-ray energy incident on the galvannealed steel sheet is Fe- An X-ray tube which is smaller than the X-ray excitation energy may be used.

(4) The galvanized hot-dip galvanized steel sheet production line according to one aspect of the present invention is characterized in that the online plating adhesion determination apparatus described in any one of (1) to (3) above is placed between the alloying furnace and the coil winding, And the sum of the plate thickness variation and the steel plate vibration is within ± 3 mm.

The adhering property can be judged in a short time by applying the on-line plating adhesion determination device of the galvannealed steel sheet of the present invention. Therefore, even when the passing speed of the steel sheet in the production line is increased, On-line measurement can be performed with high accuracy. Further, the result can be fed back to the operating conditions quickly, and the superalloy or the unalloyed alloy can be prevented in advance. As a result, even at the time of high-speed conveyance, the galvannealed galvanized steel sheet which contributes greatly to the improvement of the yield and the quality assurance can be supplied stably to the demanding customer.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram for explaining a focal size, a take-out angle, a take-out method and an actual focal size of an X-ray guide in an online plating adhesion determination apparatus according to an embodiment of the present invention.
Fig. 2 is a schematic diagram showing a main part of an online plating adhesion determination apparatus, which is an embodiment of the present invention.
3A is an optical system layout diagram of the incidence side when a solar slit is used, wherein (a) is a side view and (b) is a beam view.
Fig. 3B is a plan view of the optical system on the incident side in the case of using a multilayered parabolic mirror and a solar slit. Fig. 3B is a side view and Fig.
4 is an optical system layout diagram on the light receiving side, wherein (a) is a side view and (b) is a beam view.
5 is a plan view schematically showing a main part of the solar slit.
6 is a side view schematically illustrating the function of the multi-layered parabolic mirror.
Fig. 7 is a schematic diagram showing an example of an online plating adhesion determining apparatus according to the present invention.
8 is a schematic diagram showing a conventional online plating adhesion determination apparatus.
Fig. 9 is a graph showing the relationship between the emission beam luminance and the widthwise gain in the online plating adhesion determiner, which is an embodiment of the present invention, and is a graph comparing the present invention with the comparative example.
10 is a graph showing influences of steel plate vibration in the online plating adhesion determination apparatus, which is an embodiment of the present invention.
Fig. 11 is a result of examining the relationship between the intensity of the Γ-phase diffraction line measured by the on-line plating adhesion determination apparatus according to the present invention and the results of the off-line plating adhesion test.

An online plating adhesion determination apparatus (hereinafter, simply referred to as a determination apparatus according to the present embodiment) of an alloyed hot-dip galvanized steel sheet according to an embodiment of the present invention, (Hereinafter, simply referred to as a production line according to the present embodiment) in which the apparatus relating to the present invention is installed in a high-speed operable alloyed hot-dip galvanized steel sheet production line.

The judging device according to the present embodiment is a measuring device for measuring the thickness of a predetermined phase included in an Fe-Zn alloy of a galvannealed steel sheet and includes an X-ray tube for irradiating the galvannealed steel sheet with X- An optical system from the X-ray tube to the detector, and a detector for measuring the intensity of the diffracted X-ray obtained by X-ray irradiation. X-rays are incident on and diffracted from the galvannealed steel sheet using a parallel beam optical system as an optical system. Further, the detector is provided at a position corresponding to the diffraction angle at which the diffraction X-ray corresponding to the crystal lattice plane spacing d of 1.5 ANGSTROM or more is detected. Then, the output beam luminance of the X-ray is 20 W / mm 2 or more, and the gain in the width direction of the X-ray in the optical system is 0.15 or more.

Hereinafter, the X-ray diffraction method applied to the determination apparatus according to the present embodiment will be described. The X-ray diffraction method applied to the judgment apparatus according to the present embodiment is to measure the reflection intensity at a specific diffraction angle by irradiating a characteristic X-ray to a polycrystalline sample and classified by the Devi-Sheher method. The X-ray diffraction apparatus applicable to the judgment apparatus according to the present embodiment is constituted by an X-ray tube for generating an X-ray beam, various slits for limiting divergence of the X-ray beam, a detector, a light receiving slit, do.

The X-ray tube usable in the present embodiment generates X-rays by causing a current to flow in the filament, generating hot electrons, accelerating the hot electrons to a high voltage of several tens kV to impinge on the metal target, It is to pass through a window and take out. The metal target of the X-ray tube is selected in consideration of the absorption of the X-ray by the sample and the measurement accuracy, and Cu, Cr, Fe, Co, Mo, W and the like are used. Of these, Cu, Cr, and Co are particularly preferable because they have excellent versatility. The generated X-ray contains a K? Line or a white X-ray component in addition to a desired K? Ray. Therefore, it is necessary to remove these components and make them monochromatic. The X-ray beam is monochromated by inserting a K? Filter made of a metal foil in front of the light receiving slit or using a monochrometer. Further, it may be combined with a peaking analyzer, or a collimation system using an X-ray collimator may be employed.

It is preferable to use a slit for restricting the divergence of the X-ray beam and a slit for restricting the longitudinal divergence of the X-ray beam and a diverging slit for limiting the divergence angle in the horizontal plane to the sample. The diffracted X-ray generated by irradiating the X-ray beam onto the material surface is condensed through the light-receiving slit, and is again detected by the X-ray detector through the solar slit and the scattering slit, and the intensity thereof is measured.

Next, this embodiment will be described in more detail.

First, the X-ray tube used in the online plating adhesion determination apparatus of the galvannealed steel sheet according to the present embodiment will be described. As the X-ray tube, it is preferable to use an enclosed X-ray tube. As an X-ray source, there is a rotary-to-cathode X-ray generator in addition to an X-ray source, which is advantageous in terms of high output. However, when it is used in a galvannealed steel sheet production line, maintenance and management of a vacuum system, X-rays are good. As the enclosed X-ray tube, any of a tube for fluorescent X-rays and a tube for diffracted X-rays may be used, but a diffraction X-ray tube having a small focal spot size and high brightness is more preferable. Table 1 shows examples of the enclosed X-ray tube. The fluorescence X-ray guiding element has a relatively large focal size with respect to the diffraction X-ray guiding element, and in Table 1, the reference numerals of No.1 to 3 correspond to the guiding element for fluorescent X-ray. For the diffraction X-ray reference, the reference numerals of Nos. 4 to 15 in Table 1 correspond. The focus luminance in Table 1 is a value obtained by dividing the output W by the area of the focus (mm 2).

[Table 1]

In the specification of the X-ray tube according to the present embodiment, in addition to the output, the selection of the focal size, the extraction angle, and the extraction method are important for improving the sensitivity. Fig. 1 shows the relationship between the focal size, the extraction angle, the extraction method, and the actual focal size after extraction in the reference for diffraction X-ray. As shown in Fig. 1, a filament 10 and a metal target 11 disposed apart from the filament 10 are provided inside the X-ray tube. X-rays are generated by energizing the filaments 10 to generate thermoelectrons, which collide with the metal targets 11. On the metal target 11, a focal point 12, which is a collision area of the hot electrons, is formed. The shape of the focal point 12 has a shape close to the projected shape of the filament 10 in the metal target 11. In the example shown in Fig. 1, the width in the short direction is a (mm) (B) (mm). From the filament (10) drawing a perpendicular towards the metal target 11 and a plane perpendicular to a perpendicular to when the reference, take-out angle of m _1, m ₂ is typically 6 °.

The inclination direction of the take-out angle m _1, m is _2, there is a case for inclining manner, according to the case, a longitudinal direction of slope along the width direction of the focus 12 shown in FIG. The take-out method includes "point extraction" in which the cross-sectional shape of the X-ray beam is close to a square, and "line extraction" in which the cross-sectional shape of the extraction beam is linear along the inclination direction of the target. The actual focus size differs depending on the selection of the extraction method. Here, the actual focal size refers to the cross-sectional size of the X-ray beam immediately after being emitted to the outside of the X-ray tube port.

When the point 12 is viewed in a plane (width x length, hereinafter the same) is a (mm) x b (mm), if the point is taken out, The actual size of the focal spot 13 after taking out is a (mm) x tan (m ₁ ) · b (mm) because the lengthwise dimension of the focal size is compressed by inclining at an extraction angle m ₁ along the longitudinal direction of the focal length, . On the other hand, when the line take-out, as shown in Figure 1, by being an X-ray take-out direction is inclined to the taking out angle m ₂ along the width direction of focus, is the dimension of the focus size of the width direction compression, the actual focus after extraction The size 14 becomes tan (m ₂ ) a (mm) x b (mm). For example, assuming that the size of the focus 12 is 1 mm and the take-out angle is 6 degrees in FIG. 1, the actual focus size 13 after the point extraction is 1 (mm) x 1 ( Mm), and the actual focal spot size 14 after line extraction is 0.1 (mm) x 10 (mm).

Next, an optical system in the judgment apparatus according to the present embodiment will be described. In the judging device according to the present embodiment, a parallel beam optical system which is less susceptible to the influence of steel plate vibration at the time of on-line measurement is used. Fig. 2 shows an overall view of a parallel beam optical system. The optical system of the judging device according to the present embodiment comprises an X-ray source 21, an incident optical system 22, a light receiving optical system 23, and a detector 24. [

The X-ray source 21 shown in Fig. 2 uses the X-ray tube described above. The incident optical system 22 is provided with an exit slit 22a in order from the X-ray source 21 side, a multilayer film reflection mirror 22b having a parasitic cross-sectional contour of the reflecting surface, a solar slit 22c on the incident side, Respectively. The solar slit 22c is provided with an inlet side opening 22c ₁ for limiting the incident enlargement width of the X-ray into the solar slit 22c and an outlet side opening 22c ₁ for limiting the emission enlargement width of the X- there are (22c ₂₎ is provided. In addition, a limiting slit 22d is disposed between the solar slit 22c and the sample 25. In the judging device according to the present embodiment, the multilayer-film reflective mirror 22b may be omitted. Further, a spectral crystal may be used instead of the multilayer-film reflective mirror 22b. The parallel beam of X-rays is realized by the combination of the solar slit 22c alone or a combination of the multilayer film reflection mirror 22b and the solar slit 22c, or a spectroscopic crystal alone, or a combination of a solar slit and a spectroscopic crystal.

The emission optical system 23 is provided with an output-side solar slit 23a. The solar slit 23a is provided with an inlet side opening 23a ₁ for limiting the incident enlargement width of the X-ray into the solar slit 23a and an outlet side opening 23a ₁ for limiting the emission enlargement width of the X- a (23a ₂₎ is provided. 2, reference numeral 25 denotes an alloyed hot-dip galvanized steel sheet serving as a sample for X-ray diffraction measurement. Hereinafter, the incident optical system 22 and the light receiving optical system 23 will be described in detail.

An arrangement of the incident optical system 22 is shown in Figs. 3A and 3B. 3A shows an example in which only the solar slit 22c is used as an optical element, and X-rays obtained by point extraction are incident thereon. FIG. 3A is a side view of the sample viewed from the side, and FIG. 3A is a view (beam view of the beam) perpendicular to the beam plane from above the sample. The solar slit 22c is an optical element that is formed by laminating thin metal plates at equal intervals and limits the divergence in the vertical direction of the incident X-ray and the diffraction line in Fig. 3A. The X-ray generated from the focus 12 in Fig. 1 can suppress the vertical divergence of the incident X-rays, that is, overlapping of the vibration ring, by the incident-side solar slit 22c. Since the X-ray is generated with a spread and radiates in the form of a ring, when there is another ring-shaped X-ray distribution around the X-ray portion to be used, shift of the diffraction line occurs (Umbrella effect). The solar slit 22c determines the divergence angle? By the distance t and the length L of the metal foil 22c ₃ . This relationship is shown in Fig. When the interval t between the metal foils 22c ₃ is narrow, the field of view of the incident X-rays is limited in the height direction, so that the strength is lowered. However, the divergence in the vertical direction is suppressed and the resolution is improved.

In the present embodiment, the width (sample irradiation width) and the length (sample irradiation length) of the X-ray irradiated on the sample 25 are calculated and the emission beam luminance on the sample 25 is obtained. ) And specifications of the optical system are designed. Therefore, the method of calculating the sample irradiation width and the sample irradiation length in the case where only the solar slit 22c is used as the optical element of the incident optical system 22, . Sample irradiation width S _c is emitted beam width B _c, the distance of the sample to the exit of the solar slits (hereinafter referred to as the sample distance is called hereinafter) L, Capture angle width direction α _c and from the X-incident angle θ lines for sample, less than (1). &Quot; (1) &quot;

The outgoing beam width B _c is a value determined by the design of the optical element, but is generally about 1 mm. In Figure 3a, it represents a width of the X-ray beam passing through the outlet opening (22c ₂₎ of the solar slits (22c). The shorter the sample distance L is, the higher the signal intensity is obtained. However, considering that it is used for on-line measurement of the galvannealed steel sheet, it is considered to be about 50 mm to 150 mm.

The capture angle refers to the effective introduction angle with respect to the portion to be introduced into the optical element out of the X-rays diverging from the focal point 12 in all directions. The larger the capture angle, the larger the amount of X-rays introduced into the optical element. The capture angle width direction? _C is the angle of introduction when the optical system is viewed from the side. In the case of using the solar slit 22c, the angle of expansion of the X-ray beam passing through the solar slit 22c, and α _c is generally in the range of 0.1 to 0.6 °. The incident angle &amp;thetas; of the X-ray with respect to the sample 25 is usually set to about half of the diffraction angle.

Next, as shown in (b) of Figure 3a, the sample irradiated length S _L is, the actual focal length of the X-ray beam X _L, Goniometer radius R and from Capture angle longitudinal α _L, the following expression (2 ).

Actually, the focal length X _L is the cross-sectional length of the actual focus 13, 14 after taking-out shown in Fig. The gonio radius R is the distance from the actual focus 13, 14 to the sample 25. The capture angle longitudinal direction alpha _L is the angle of introduction when the optical system is viewed from above the sample. When the solar slit 22c is used, the angle of expansion of the X-ray beam passing through the solar slit, and alpha _L is generally in the range of 3 to 8 degrees.

Next, Fig. 3B is a layout diagram of the incident optical system in the case where the solar slit 22c and the multi-layered parabolic mirror 22b are used as the optical element, and the X-ray line extracted therefrom is incident thereon. FIG. 3B is a side view of the sample viewed from the side, and FIG. 3B is a view (beam view of the beam) perpendicular to the beam surface from above the sample. The multi-layer parabolic mirror 22b refers to a parabolic mirror with a lattice plane spacing and has a parabolic surface shape such that the capture angle width direction? _C is maximized as shown in Fig. 6, And a slope is formed at the lattice plane interval so as to reflect Bragg in parallel at the position. Details are given in the following references. In the case of using a multilayer mirror, the width direction indicates the longitudinal direction of the mirror surface viewed from the X-ray source. The value of the capture angle width direction α _c of the multilayer parabolic mirror is generally in the range of 0.4 to 0.7. On the other hand, in the flat multilayer mirror, conditions for Bragg reflection are determined due to a certain lattice spacing. Thus, the value of the capture angle width direction? _C of the flat multilayer mirror corresponds to the width of the locking curve of the mirror, which is also determined by the design value of the mirror, but is generally in the range of 0.05 to 0.10. Capture angle The longitudinal direction α _L indicates the length of the source in the optical system, but this is determined by the width of the solar slit exit.

References: Structural Properties Vol.10, No. 1, P20 ~ 29, 2004, published by Agnes Technology Center

A method of calculating the sample irradiation width and the sample irradiation length in the case where the multilayer parabolic mirror 22b is used in addition to the solar slit 22c as the optical element and the X-ray extracted therefrom is incident thereon is described using FIG. 3B do. The sample irradiation width S _c is calculated from the following equation (3) from the exit beam width B _c , the sample distance L, and the X-ray incidence angle θ.

In the formula (3),? Is an enlargement angle between the exit beam emerging from the solar slit 22c and the sample, and is a value determined by the design of the multilayer paraboloid mirror 22b . In the example of Table 3, 0.05 DEG was used as a general value. B _c is a value determined by the design of the optical element, and is generally about 1 mm. In Figure 3b, it represents a width of the X-ray beam passing through the outlet opening (22c ₂₎ of the solar slits (22c). L and &amp;thetas; are as described in Fig. 3A.

The sample irradiation length S _L is calculated from the slit exit focal length X _Lo , the sample distance L, and the capture angle longitudinal direction alpha _L by the following equation (4).

The slit exit focal length X _Lo is equal to the slit length of the limiting slit 22d in this case. The sample distance L and the capture angle longitudinal direction alpha _L are as described above.

The diffraction angle used in the determination apparatus according to the present embodiment is an angle corresponding to a crystal lattice plane interval d of 1.5 ANGSTROM or more. This is shown in Table 2. In the present embodiment, the fact that the diffraction angle corresponds to the crystal lattice plane interval d means that the range finely adjusted within ± 0.5 degrees is included. Particularly, in the present embodiment, it is preferable to employ diffraction angles corresponding to the crystal lattice plane spacings d of Nos. 5, 7, 9, 10, 12, 13 and 15. These diffraction angles have a relatively high correlation coefficient between the diffraction intensity at each diffraction angle and the thickness of the alloy phase such as ζ phase, δ ₁ phase and Γ · Γ ₁ phase, so that the adhesion of the plating layer can be evaluated with high accuracy Is the desired diffraction angle.

[Table 2]

Next, the light-receiving optical system 23 will be described. An arrangement example of the light receiving optical system is shown in Fig. 4 (a) is a side view of the specimen viewed from the side, and Fig. 4 (b) is a plan view of the specimen as viewed from above the specimen and perpendicular to the beam plane (Beam shave). The role of the solar slit 23a in the light receiving optical system 23 is an improvement in resolution. The principle is already shown in Fig. The product of the beam width R _c of the X-ray beam incident on the detector 24 and the beam height R _L becomes the effective area of the X-ray beam in the detector 24. In order to introduce as many signals as possible even if the steel plate position is displaced, the wider the effective area, the better.

Next, examples of the X-ray detector that can be used in the judging device according to the present embodiment include a proportional counter (PC) for performing ionization by X-rays with gas, a scintillation counter (SC: Scintillation Counter), a semiconductor detector (SSD: Solid State Detector) used in a semiconductor device, and the like. The proportional counter has a gas flow type that operates while flowing gas, and an enclosed type that is sealed in a metal container. Semiconductor detectors include Si (Li) type detectors that are used while cooling with liquid nitrogen, and silicon drift detectors (SDD) that do not use liquid nitrogen by electron cooling. The proportion of the scintillation counter is higher than that of the scintillation counter, and the semiconductor detector has a superior discriminating ability (energy resolution) of X-rays incident on the detector. However, It is not very much on the market to have an effective area. The scintillation counter tube and the proportional counter tube are comparatively inexpensive and suitable for the diffracted X-ray analysis can be manufactured relatively easily, which is also suitable in the present embodiment.

When the energy of the incident X-ray is higher than the excitation energy of the Fe-K? Fluorescent X-ray of the steel sheet in the case of the sample of the hot-dip galvanized steel sheet, the X- ray incident on the detector 24 is the diffracted ray of the incident X- It is on both sides of the line. The fluorescent X-ray of iron is treated as a noise component for the diffraction line, and the reliability of the obtained X-ray information is lowered. Therefore, when the energy of the X-ray is lower than the excitation energy of the Fe-K alpha fluorescent X-ray, for example, Co-K alpha is selected, generation of fluorescent X-rays of iron can be suppressed. As a result, And it is suitable for use as the judging device according to the present embodiment. In this case, however, since the Zn-K? Fluorescent X-ray is not excited, it can not be used also as the X-ray source of the Zn deposition amount meter.

The judgment apparatus according to the present embodiment is designed such that the two parameters such as the "emitted beam luminance" and the "lateral direction gain" exceed the specified lower limit on the premise of the parallel beam optical system, by designing the X- So that the diffraction peak of the diffraction grating can be detected with high sensitivity. Therefore, the &quot; outgoing beam luminance &quot; will be described first.

The &quot; emitted beam luminance &quot; is the luminance of the X-ray per sample irradiated area. The procedure for calculating this is as follows.

1) Find the effective focus luminance.

2) Capture correction and reflectance correction are performed.

3) The emission beam luminance is obtained from the correction and the sample irradiation area.

The effective focus luminance is a value obtained by dividing the X-ray output by the actual focus area. The actual focal area is obtained from the actual focal size described in Fig. 1 as follows.

In the point extraction, the actual focus is approximated by an ellipse approximation, and in the line extraction, a rectangular approximation is calculated, and a value close to the measured value is obtained.

Next, Capture correction is performed in consideration of the extent to which the X-ray output per unit area of the actual focus is introduced in the width direction and the longitudinal direction, and the reflectance is corrected to what extent the reflection of the mirror is utilized. The correction formula is as follows.

Capture correction is to correct how much (width / length product) is used for the effective focus luminance (all X-ray intensity diverging from the X-ray source). The reflectance correction is a product of the reflectance of the optical element in the width direction and the length direction.

The value obtained by dividing the correction value obtained in the expression (8) by the sample irradiation area is &quot; emitted beam luminance &quot;. The sample irradiation area is the product of the sample irradiation width S _c and the sample irradiation length S _L described in FIGS. 3A and 3B. The larger the outgoing beam luminance, the larger the signal intensity of the diffraction line, and the diffraction peak having excellent sensitivity and excellent quantitative characteristics can be obtained.

Next, the &quot; width direction gain &quot; will be described. The lateral direction gain is calculated by the following equation.

The width direction gain is an index indicating how much the device is expected in the width direction and how much reflection is used when an optical element such as a mirror is viewed from the X-ray source. The larger the lateral direction gain means that the optical element can be used effectively, the X-rays from the source can be effectively introduced, parallelized, reflected, and guided to the sample.

In the judgment apparatus of the present embodiment, the emission beam luminance is preferably 20 W / mm 2 or more, more preferably 50 W / mm 2 or more, and further preferably 80 W / mm 2 or more. If the emission beam luminance is 20 W / mm &lt; 2 &gt; or more, the diffraction intensity can be increased, and the time required for the determination can be greatly shortened.

Further, the gain in the width direction is preferably 0.15 or more, more preferably 0.25 or more, and still more preferably 0.35 or more. When the lateral direction gain is 0.15 or more, the utilization ratio of the X-rays can be increased, whereby the diffraction intensity can be increased and the time required for the determination can be greatly shortened.

In setting the judging device according to the present embodiment on a galvannealed galvanized steel sheet production line, the range of the installation position may be within a range from the completion of the alloying to the coil winding. In addition, it is necessary to consider the influence of plate thickness fluctuation and steel plate vibration. Although described in the following embodiments, the performance of the apparatus is not affected by the measurement sensitivity if the fluctuation from the reference position of the sample is within ± 3 mm. Normally, since the plate thickness fluctuation width is considered to be about 3 mm, it is preferable to install the steel plate in a controlled place such that the steel plate vibration width is within 3 mm. As the vibration control method, a known method such as support by a touch roll, winding on a roll, installation of a vibration suppression device, and the like may be applied.

In the present embodiment, a solar slit and a multilayer film parabolic mirror are exemplified as optical elements usable in the optical system. However, the present invention is not limited to this, and a flat multilayer mirror having a flat reflective surface, LiF, pyro graphite, Si A spectroscopic crystal such as Ge, and the like can be used. When the spectroscopic crystal is used for the incident optical system and then the solar slit is used in combination as in Embodiment B, the sample irradiation width is determined by the formula (1) and the sample irradiation length by the formula (4).

Hereinafter, a concrete example of the determination apparatus according to the present embodiment will be described with reference to FIG.

As a representative example of the on-line measuring apparatus, a specific configuration of an apparatus for detecting Γ · Γ ₁ phase in the Fe-Zn alloy phase will be described with reference to FIG.

Fig. 7 is a schematic diagram of an on-line measuring apparatus of Γ · Γ ₁ in the case where a Co diffraction guidewire is used as an X-ray guiding unit. The X-ray extraction method is a line extraction method. In Fig. 7, illustration of a slit, a coefficient recording device and the like is omitted. In this measuring apparatus, the X-ray diffraction angle 2? Is set to 55.86 °. When the X-ray is irradiated to the coil 32 from the X-ray tube 31, a plurality of diffracted X-rays having different diffraction angles are generated. In the detector 33, the intensity of the diffracted X-ray corresponding to the crystal lattice plane spacing d = 1.914 Å on Γ · Γ ₁ is measured. In the detector 34, the background intensity at the high angle side is measured. The background measurement angle can be appropriately determined in the vicinity of the diffracted X-ray corresponding to d = 1.914A detected by the detector 33 on the basis of the X-ray diffraction pattern. For example, A measurement angle spaced from the X-ray can be employed. In practice, it is desirable to obtain an appropriate background measurement angle off-line prior to on-line measurement. When the angle difference between the diffracted X-ray and the background is 5 degrees or less, it is physically difficult to dispose the detector 34. Therefore, the diffracted X-ray detector 33 is used to scan by a predetermined angle in the vicinity of the diffraction angle , And the background may be obtained.

By using the above-mentioned diffracted X-ray intensity, the amount of? G? ₁ phase can be measured. The quantification on Γ · Γ ₁ can convert the value obtained by subtracting the background intensity from the diffracted X-ray intensity, for example, to the amount of the image based on the previously prepared calibration curve.

As a comparison, the configuration of a high-angle-side Fe-Zn phase peak measuring apparatus according to the prior art is shown in Fig.

The determination device shown in Fig. 8 is an on-line measurement device for simultaneously measuring two-phase or three-phase diffraction X-rays among Γ · Γ ₁ phase, δ ₁ phase, and ζ phase included in Fe-Zn alloy phase. In the figure, reference numeral 41 denotes a fluorescent X-ray guide target which targets Cr. Reference numeral 47 denotes a coil. The detector 42 detects a diffracted X-ray corresponding to d = 1.222 占 on Γ · Γ ₁ , detects a diffracted X-ray corresponding to d = 1.260 Å on the ζ phase in the detector 43, and detects diffracted X-rays corresponding to d = 1.279A on delta ₁ phase. The detector 45 measures the background intensity at the high angle side, and the detector 46 measures the background intensity at the low angle side.

As described above, according to the judging device of the present embodiment, since the optical system for irradiating the X-ray parallel beam to the galvannealed galvanized steel sheet is provided as the optical system, even if the galvannealed steel sheet running on the carrying line oscillates, The incident angle of the X-ray is constant in the beam, so that the diffraction angle of the X-ray can be made constant and the detection sensitivity of the diffracted X-ray can be increased. Further, since the outgoing beam luminance is 20 W / mm 2 or more and the lateral direction gain is 0.15 or more, the diffraction intensity of the X-ray is high and the time required for the judgment can be greatly shortened.

Further, according to the determination apparatus of the present embodiment, the detector 24 is, the crystal lattice plane spacing d is provided at the position of diffraction angle for detecting the diffracted X-rays corresponding to that by 1.914Å, Γ · thickness on Γ ₁ Can be measured with high accuracy, and adhesion of the plating layer can be determined with high accuracy. Further, according to the judging device of the present embodiment, as the X-ray tube, by using an X-ray tube whose energy of the X-ray incident on the galvannealed steel sheet becomes smaller than the fluorescent X-ray excitation energy of Fe- The detection sensitivities of the three phases of Γ · Γ ₁ phase, δ ₁ phase, and ζ phase contained in phase can be increased.

Further, according to the manufacturing line of the present embodiment, the above-described judging device in which the determination time is shortened is placed at a position between the alloying furnace and the coil winding until the sum of the plate thickness fluctuation and the steel plate vibration is within ± 3 mm It is possible to shorten the length of the steel sheet required for determination of the adhesion even when the passing speed of the galvannealed hot dip galvanized steel sheet is increased to enable quality assurance over the entire length of the coil and to facilitate quick feedback to the operating conditions It becomes.

Example

Next, the present invention will be described using examples.

In the first embodiment, by designing specifications of the X-ray tube and the optical system such that the &quot; outgoing beam luminance &quot; and the &quot; lateral direction gain &quot; are changed by using the parallel beam optical system, Fe How the intensity of the low angle peak on the Zn phase changes, and the like. In the second embodiment, the judgment device according to the present embodiment is installed in a galvannealing hot-dip galvanizing line and online measurement results are described. The present invention is not limited to the following examples.

(Example 1)

A sample of the galvannealed galvanized steel sheet produced in the actual line was prepared as the disclosed steel sheet. The amount of Zn deposited was 45 g / m 2, and Fe (%) in the plating layer was 9.5% and 10.5%. The off-line plating adhesion was 9.5% (A rating) and 10.5% was close to the boundary (C rating). Using these, the levels shown in Tables 3A to 3D were measured in the laboratory.

An X-ray tube was used for fluorescent or diffraction-sealed X-ray tubes using Cr, Cu, and Co as metal targets, which differ in output, focal size, and extraction method. In the diffraction X-ray tube, the extraction angles are all 6 degrees. As the fluorescent X-ray tube, the focal spot size on the target was 7 mm x 7.5 mm, and the inclination angle of the target with respect to the electron beam from the filament was 26 °. In this case, the effective focus size of the extracted X-rays is 7 mm x 7 mm.

As the optical element of the incident optical system, the following combination was used. The combination of the optical elements together with the symbols in Table 3B is shown.

"-" ... SOLAR Slit only

"A" ... Solar slit and multilayer parabolic mirror

"B" ... Solar slit and pyro graphite

"C" ... Solar slit and flat multilayer mirror

A solar slit was used for the optical element of the light receiving optical system. The following was used for the detector. Symbol in Table 3B indicates the type of detector.

"S-PC" ... Sealed gas proportional counter

"SDD" ... Semiconductor detector

"SC" ... Scintillation counter

The obtained diffraction signals of the Fe-Zn phase were evaluated from the following viewpoints.

Strength (cps):

Using a steel sheet having Fe (%) of 9.5% in the plating layer, a value obtained by subtracting the background intensity from the peak intensity was obtained as the strength. The background was a straight line connecting both ends of the peak. The measurement time was 0.1 sec.

Judgment time (sec):

The strengths of the steel sheet with the Fe (%) of 9.5% and the steel sheet with 10.5% of the plated layer were compared and the measurement time required for the difference between them to be three times the measurement error (theoretical standard deviation) was obtained. When the peak intensity of the Γ phase is measured, it corresponds to the measurement time necessary for determining whether or not the adhesion is successful.

Vibration tolerance (mm):

A steel plate having Fe (%) of 9.5% in the plating layer was used, and the change of the peak intensity was examined while changing the sample position, and the extent to which the displacement due to vibration was acceptable was evaluated. An example of the result is shown in Fig. In this case, it is determined that vibration of ± 3 mm is acceptable.

The results are shown in Tables 3A to 3D. In Nos. 1 to 28, the specifications of the X-ray tube and the optical system are designed so that the width direction gain and the emission beam luminance become higher in the comparative example of the present invention. This relationship is shown in Fig. Comparing the signal characteristics of Table 3, the signal strength of the present example is higher than that of the comparative example, the determination time is shorter, and the tolerance of the vibration is ± 3 mm. As a result, the measurement time can be shortened by the high-speed transfer plate and the measurement can be performed without any problem even if the vibration is intensified. In other words, it is highly responsive to high-speed operation.

Nos. 29 to 31 are measurement examples of Fe-Zn phase peaks on the high angle side according to the prior art. The intensity of the signal is high and the vibration of the steel sheet can be tolerated. However, there is a problem in peak separation of each phase in the initial stage, and the difference in the Fe (%) in the plating layer can not be accurately determined.

[Table 3A]

[Table 3B]

[Table 3C]

[Table 3D]

(Example 2)

The determination device according to the present embodiment was installed in a galvannealed galvanized steel sheet production line. The installation position is a horizontal path and a roll winding portion after completion of alloying. The configuration of the apparatus is as shown in Fig. The specifications of the device are as shown in No. 6 in Table 3.

A galvannealed galvanized steel sheet was manufactured at a line speed of 180 mpm in a production line. During the production of the galvannealed hot-dip galvanized steel sheet, the alloying temperature was intentionally changed from the optimum alloying temperature to the superalloy temperature, so that good cohesive parts and poor parts were present in one coil. This test was repeated on three coils. The adhesion was evaluated in the off-line by the sampling from the front part, the middle part and the tail part of the coil and the adhesion evaluation was evaluated as A evaluation (pass), B evaluation (close to the boundary of acceptance but passed), C evaluation Close to the border, but failed). These samples were subjected to electrostatic charge electrolysis to peel off the plating layer leaving only the Γ-upper single layer, and the intensity of the diffraction line on the Γ-phase was obtained in the off-line state.

On the other hand, at the time of manufacturing the above-described coils, the determination apparatus according to the present embodiment shown in Fig. 7 was operated to measure the diffraction line intensity on the Γ-line on-line. Fig. 11 is a graph plotting the result of plotting the diffracted line intensity of the Γ-upper single layer in the off-line on the abscissa and the abscissa on the abscissa.

From Fig. 11, it can be seen that the determination device according to the present embodiment can accurately determine the adhesion of the galvanized hot-dip galvanized steel sheet, similarly to the off-line evaluation, even when the galvannealed steel sheet is operated at a high line speed of 180 mpm.

While the preferred embodiments of the present invention have been described in detail with reference to the drawings, the present invention is not limited to these examples. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the scope of the invention as defined in the appended claims. Of the present invention.

According to the present invention, an alloyed hot-dip galvanized steel sheet with stable quality can be supplied inexpensively and stably, and the spread of automobiles with excellent rust prevention is gradually promoted. This leads to an improvement in the life span and safety of the vehicle, and also contributes to improvement of the global environment in terms of resource saving. Therefore, the value of industrial use is extremely large.

21: X-ray source (X-ray tube)
22: Incident optical system (optical system)
24: Detector

Claims (4)

An X-ray guide for radiating X-rays toward the galvannealed galvanized steel sheet running on the conveying line;
An optical system for irradiating and diffracting the X-ray generated from the X-ray tube to the galvannealed steel sheet as a parallel beam;
A detector provided at a position for detecting the diffracted X-ray measuring intensity of the diffracted X-ray and detecting a diffracted X-ray corresponding to a crystal lattice plane interval d of 1.5 ANGSTROM or more;
And,
Wherein an outgoing beam luminance of the X-ray is 20 W / mm 2 or more, and a gain in the width direction of the X-ray in the optical system is 0.15 or more. The method according to claim 1,
Wherein the detector is provided at a position of a diffraction angle for detecting the diffracted X-ray having a crystal lattice plane spacing d of 1.914 angstroms. 3. The method according to claim 1 or 2,
Wherein the X-ray tube is an X-ray tube having an energy of X-rays incident on the galvannealed steel sheet smaller than a fluorescent X-ray excitation energy of Fe-K alpha is used for on-line plating of the galvannealed galvanized steel sheet Apparatus for determining adhesion. The online plating adhesion determination device according to any one of claims 1 to 3 is provided at a position between the alloying furnace and the coil winding until the sum of the plate thickness fluctuation and the steel plate vibration is within ± 3 mm , High-speed operation alloyed hot-dip galvanized steel sheet manufacturing line.

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